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Home arrow Computer Science arrow Harmonic Balance Finite Element Method: Applications in Nonlinear Electromagnetics and Power Systems
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References

[1] Glover, J.D., Sarma, M.S. and Overbye, T.J. (2011). Power System Analysis and Design, Fifth Edition. Cengage Learning.

[2] Lu, J., Yamada, S. and Bessho, K. (1990). Development and Application of Harmonic Balance Finite Element Method in Electromagnetic Field. International Journal of Applied Electromagnetics in Materials 1(2-4), 305-316.

[3] Yacamini, R. and Bronzeado, H. (1994). Transformer inrush calculations using a coupled electromagnetic model. IEE Proceedings - Science, Measurement and Technology 141(6), 491-498.

[4] Enringt, W.G. (1996). Transformer models for electromagnetic transient studies with particular reference to HV DC transmission. D. Eng. dissertation, University of Canterbury, New Zealand.

[5] Wang, J., Zhang, K. and Wang, X. (1999). Finite element method using harmonic balance, Journal of Xi’an Jiaotong University 33(12), 5-10.

[6] Hantila, F., Preda, G. and Vasiliu, M. (2000). Polarization method for static fields. IEEE Transactions on Magnetics 36(4), 672-675.

[7] NERC (2013). Appliaction Guide - Computing Geomagnetically-Induced Current in the Bulk-Power System.

[8] Pirjola, R. (2007). Calculation of geomagnetically induced currents (GIC) in a high-voltage electric power transmission system and estimation of effects of overhead shield wires on GIC modelling. Journal of Atmospheric and Solar-Terrestrial Physics 69, 1305-1311.

[9] Kappenman, J.G. and Albertson, V.D. (1990). Bracing for the Geomagnetic Storm. IEEE Spectrum March, 27-33.

[10] ABB (no date). SolidGroundTM GIC grid stability and harmonics mitigation system, Geomagnetic Storm Induced Current (GIC) and Electromagnetic Pulse (EMP) protection. Available at: www. abb.us/highvoltage.

[11] Ngnegueu, T., Marketos, F., Devaux, F. et al. (2012). Behaviour of transformers under DC/GIC excitation: Phenomenon, Impact on design/design evaluation process and Modelling aspects in support of Design, A2-303. CIGRE 21. Available at: http://www.cigre.org

[12] Lu, S. and Liu, Y. (1993). FEM analysis of DC saturation to assess transformer susceptibility to geomagnetically induced currents. IEEE Transactions on Power Delivery 8(3), 1367-1376.

[13] Mousavi, S.A. (2015). Electromagnetic Modelling of Power Transformers for Study and Mitigation of Effects of GICs, Chapter 5. Numerical modelling and calculation of power Transformers. PhD thesis, Royal Institute of Technology (KTH).

[14] Siemens AG Energy Sector (2014). Designed to Withstand-Siemense GlC-safe transformers. Published by and copyright © 2014: Siemens AG Energy Sector Freyeslebenstrasse 1 91058 Erlangen, Germany. Available online at: siemens.com/energy/transformers

[15] Zhao, X., Lu, J., Li, L., Cheng, Z. and Lu, T. (2011). Analysis of the DC bias phenomenon by the harmonic balance finite element method. IEEE Transactions on Power Delivery 26(1), 475-485.

[16] Biro, O., Buchgraber, G. Leber, G. and Preis, K. (2008). Prediction of magnetizing current wave-forms in a three-phase power transformer under DC bias, IEEE Transactions on Magnetics 44(6), 1554-1557.

[17] Power IT Lab (no date). GIC Impact for Transformer Harmonics and Reactive Power. The University of Tennessee. Available at: http://powerit.utk.edu/GIC_impact.html

[18] Pan, Z. and Liu, Y. (2014). Harmonics current and reactive power consumption of threephase seven- limb transformer during geomagnetically disturbance. Technical report.

[19] Li, X., Wen, X., Markham, P. and Liu, Y. (2010). Analysis of nonlinear characteristics for a three phase, Five limb transformer under DC bias. IEEE Transactions on Power Delivery 25(4), 2504-2510.

[20] IEEE Std. 519-2014 (2014: revision of IEEE Std. 519, 1992). IEEE Recommended Practices and Requirements for Harmonic Control in Electric Power Systems. Approved 27 March 2014.

[21] Garcia-Gracia, M., El Halabi, N., Alonso, A. and Paz Comech, M. (2011). Harmonic Distortion in Renewable Energy Systems: Capacitive Couplings. Available online at www.intechopen.com.

[22] Bouloumpasis, I., Vovos, P., Georgakas, K. and Vovos, N.A. (2015). Current Harmonics Compensation in Microgrids Exploiting the Power Electronics Interfaces of Renewable Energy Sources. Energies 8(4), 2295-2311.

[23] Gao Xiaozhi, Li Linchuan and Chen Wengan (2011). Power quality improvement for microgrid in islanded mode. Procedia Engineering 23, 174-179.

[24] Wang Chengshen, Xiao Zhaosia and Wang Shouxiong (2008). Synthetical control and analysis of microgrid. Industrial Automation of Electric Power Systems 32(7), 98-103.

[25] Blaabjerg, F., Trodorecer, R., Liserre, M. and Timbas, A.V. (2006) Overview of control and grid synchronization for distributed power generation systems. IEEE Transactions on Industrial Electronics 53, 1398-1409.

 
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